Jingwei Wang , Junyang Tan , Liqiong He , Zhenqing Li , Shengnan Li , Yunhao Zhang , Huiyu Nong , Qinke Wu , Qiangmin Yu , Xiaolong Zou , Hui-Ming Cheng , Bilu Liu
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引用次数: 0
Abstract
Non-layered two-dimensional (2D) materials have sparked much interest recently due to their atomic thickness, large surface area, thickness- and facet-dependent properties. Currently, these materials are mainly grown from wet-chemistry methods but suffer from small size, low quality, and multi-facets, which is a major challenge hindering their facet-dependent property studies and applications. Here, we report the facet-engineered growth (FEG) of non-layered 2D manganese chalcogenides (MnX, X = S, Se, Te) based on the chemical vapor deposition method. The as-grown samples exhibit large-area surfaces of single facet, high-crystallinity, and ordered domain orientation. As a proof-of-concept, we show the facet-dependent electrocatalytic property of non-layered 2D MnSe, proving they are ideal candidates for fundamental research. Furthermore, we elucidate the underlying mechanism of FEG during the vapor growth process by the interfacial energy derived nucleation models. The method developed in this work provides new opportunities for regulating and designing the structure of 2D materials.
非层状二维(2D)材料由于其原子厚度、大表面积、厚度和面相关的特性,最近引起了人们的广泛关注。目前,这些材料主要通过湿化学方法生长,但存在尺寸小、质量低、多面性等问题,这是阻碍其基于面性的性质研究和应用的主要挑战。在这里,我们报道了基于化学气相沉积法的非层状二维硫属锰(MnX, X = S, Se, Te)的面工程生长(FEG)。生长后的样品具有大面积的单面表面、高结晶度和有序的畴取向。作为概念验证,我们展示了非层状二维MnSe的面依赖电催化特性,证明它们是基础研究的理想候选者。此外,我们还通过界面能衍生成核模型阐明了蒸汽生长过程中FEG的潜在机制。该方法为调节和设计二维材料的结构提供了新的机会。
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